Method for fabricating asymmetric double-gate transistors by which asymmetric and symmetric double-gate transistors can be made on the same substrate

ABSTRACT

A method for fabricating a microelectronic device with one or plural asymmetric double-gate transistors, including: a) forming one or plural structures on a substrate including at least a first semiconducting block configured to form a first gate of a double-gate transistor, and at least a second semiconducting block configured to form a second gate of the double-gate transistor, the first block and the second block being located on opposite sides of at least one semiconducting zone and separated from the semiconducting zone by a first gate dielectric zone and a second gate dielectric zone respectively, and b) doping at least one or plural semiconducting zones in the second block of at least one given structure among the structures, using at least one implantation selective relative to the first block.

TECHNICAL FIELD

The invention relates to the field of microelectronic devices equipped with double-gate transistors and relates to an improved method for fabricating asymmetric double-gate transistors.

The invention also relates to a method for fabricating a microelectronic device provided with one or several symmetric double-gate transistors and one or several asymmetric double-gate transistors co-integrated on the same substrate.

The invention is also applicable to the field of random access memories such as SRAM (Static Random Access Memory).

PRIOR ART

It is known how to make double-gate transistors with two independent gates that have symmetric electrical characteristics or identical behaviour for the same polarisation. A double-gate transistor is a transistor that comprises independent first and second gates formed on each side of an active zone, the first gate and the second gate being connected or not connected to each other.

Double-gate transistors may be made using a so-called “planar” structure, formed from a first gate and a second gate arranged such that the first gate, a semiconducting zone that is intended to form one or several channels, and the second gate are superposed on a substrate.

Double-gate transistors may also be made using a so-called “finFET” type structure. In this type of transistor, the double-gate is formed from a first gate and a second gate arranged such that the first gate, a semiconducting zone that is intended to form one or several channels, and the second gate are placed adjacent to each other on a substrate.

It is also known how to make asymmetric double-gate transistors. An asymmetric double-gate is formed from two separate gates that are dissymmetric about the principal plane of a semiconducting zone that is intended to form one or several channels, and these gates are placed on each side of this semiconducting zone.

So-called “non self-aligned” methods have been developed to make asymmetric transistors with planar structure, in other words transistors for which each gate is defined by a different lithography.

Document [ILL05] discloses an example embodiment of an asymmetric double-gate transistor using a non self-aligned method.

FIGS. 1A-1E show different examples of fabricating an asymmetric planar double-gate structure.

One solution for fabricating asymmetric transistors using a non self-aligned technology consists of forming a first gate or back gate intentionally offset from the second gate or front gate, and/or with a smaller critical dimension than the dimension of front gate.

FIG. 1A shows an example of a structure of an asymmetric planar double-gate transistor. This structure is provided with a first gate 10 or back gate in contact with a first gate dielectric layer 11, and a second gate 14 formed on a second gate dielectric layer 13, a semiconducting active zone 12 that is intended to form one or several channels being located between the first dielectric layer 11 and the second dielectric layer 13. The first gate 10 and the second gate 14 are offset such that part of the first gate 10 is not facing the second gate 14 and part of the second gate is not facing the first gate 10. In this example, the offset Δ between the two gates 10 and 14 is such that Δ=D1, for example where D1 is of the order 30 nanometers

Another example of dissymmetry is shown in FIG. 1B. In this figure an asymmetric planar double-gate transistor is provided with a first gate 20 formed below a semiconducting active zone 12 and facing a second gate 24 with a critical dimension less than the dimension of first gate, and formed above said semiconducting active zone 12. The second gate 24 and the first gate 20 are offset such that the second gate 24 is entirely facing the first gate 20, while part of the second gate 24 is facing the semiconducting active zone 12 but is not facing the second gate 24. In this example the offset Δ between the two gates 20, 24 is such that Δ=+D2 for example where D2 is of the order of 15 nanometers.

FIG. 1C shows another example of a structure of an asymmetric planar double-gate transistor. This structure is provided with a first gate 30 or lower gate with a critical dimension dc₁, and a second gate 34 or upper gate with a critical dimension dc₂ greater than dc₁.

FIG. 1D shows another example of a structure of an asymmetric planar double-gate transistor. This structure is provided with a first gate 40 or lower gate with a given critical dimension, and a second gate 44 or upper gate with a larger critical dimension. The offset Δ between the two gates is such that Δ=−D1.

FIG. 1E shows another example of a structure of an asymmetric planar double-gate transistor. This structure is provided with a first gate 50 or lower gate with a critical dimension dc₁, and a second gate 54 or upper gate, the offset Δ between the two gates being such that Δ=−D2.

The leakage current I_(off) of the transistor can be adjusted by adjusting the offset Δ between the two gates of an asymmetric double-gate.

In FIG. 2, the curves C₁₁ and C₁₂ represent simulations and measurements respectively of a leakage current I_(off) from an asymmetric double-gate structure as a function of the offset Δ between its lower and upper gates. Each of the gates has a critical dimension of the order of 70 nanometers, while the channel thickness is of the order of 10 nanometers.

It is difficult to obtain a precise offset Δ between the gates with methods that are not self-aligned. A controlled and very small offset Δ, for example of the order of 2 to 5 nanometers, is required for some applications.

The lack of precision of “non self-aligned” production methods also causes a problem for implementing symmetric double-gate transistors. The results currently obtained with such methods show that it is difficult to obtain two gates with the same length and that are well aligned. In particular, this deteriorates dynamic operation of transistors made using such a method.

Self-aligned production methods, in other words methods in which the two gates are defined by the same lithography step, have been developed to make it possible to benefit from the intrinsic advantages of planar double-gate structures. For example, document [DEL01] describes such a method.

The problem of finding a new method for fabricating asymmetric double-gate transistors then arises.

PRESENTATION OF THE INVENTION

The invention relates to a method for fabricating a microelectronic device with one or several double-gate transistors, comprising the following steps:

a) formation of one or several structures on a substrate comprising at least one first block, that is intended to form a first gate of a double-gate transistor, and at least a second block that is intended to form the second gate of said double-gate, the first block and the second block being located on opposite sides of at least one semiconducting zone and separated from the semiconducting zone by a first gate dielectric zone and a second gate dielectric zone, respectively, the structures being made such that the critical dimension of the first block and the second block is less than the critical dimension of the second isolating zone and/or the first isolating zone

b) doping of at least one or several semiconducting zones in the second block of at least one given structure among said structures, using at least one implantation step selective relative to the first block.

Selective implantation means that the first block is not implanted, or is less implanted than the second block.

Such an implantation step can be used to make asymmetric double-gates.

In fabricating the first block and the second block with a critical dimension less than the critical dimension of the second isolating zone and/or the first isolating zone, the second isolating zone and/or the first isolating zone may form means of protecting the first block against implantation.

The first implantation may be done at a predetermined non-zero angle from a normal to the principal plane of the substrate passing through the semiconducting zone.

According to one possibility, said implantation can be done in zones in the second block located close to and/or in contact with the second dielectric zone.

According to one particular embodiment, said implantation may be done on a first side of the structure, the part of the structure on the other side of a normal to the principal plane of the substrate passing through the semiconducting zone not being implanted.

The method may include at least one selective etching step c) between non-implanted semiconducting zones of said blocks and implanted semiconducting zones of the second block, after step b).

This makes it possible to make asymmetric double-gates with different critical dimensions.

Selective etching may be selective between non-doped semiconducting zones and semiconducting zones doped using said implantation.

According to one variant, selective etching may be selective between semiconducting zones doped using a given type of doping and semiconducting zones doped by said implantation using another type of doping different from the given type of doping.

The structures may be so-called “planar” structures such that the first block is supported on the substrate, the first block, the semiconducting zone and the second block being superposed on top of said substrate.

The second block may be covered by a hard mask in step b), the critical dimension of the hard mask being larger than the critical dimension of the second block.

In this way, the hard mask can form means of protecting the upper part of the second block from the implantation.

According to one possible embodiment of the structure, the first block and/or the second block may be based on a semiconducting material.

According to one variant, the first block and/or the second block may be formed from at least one metallic layer and at least one stacked semiconducting layer respectively.

The method according to the invention can be used to make asymmetric and symmetric double-gate transistors on the same substrate.

In this case, in step b), at least one particular structure among said structures formed in step a) is protected during the doping step done in step b), by means of at least one protection layer, for example based on resin or a hard mask layer based on a dielectric material for example such as SiO₂ or Si₃N₄, said particular structure being designed to form a symmetric double-gate transistor.

Then, the first block and the second block in this particular structure may be etched at the same time as the first block and the second block of said given structure, said given structure being designed to form an asymmetric double-gate transistor, while the particular structure is designed to form a symmetric double-gate transistor.

The invention also relates to a method for fabricating a structure of a random access memory cell provided with asymmetric double-gate transistors comprising a method like that defined above.

The invention also relates to a method for fabricating a structure of a random access memory cell provided with asymmetric double-gate transistors and symmetric double-gate transistors using a method like that described above.

The memory can be a static random access memory SRAM.

BRIEF DESCRIPTION OF THE DRAWINGS

This invention will be better understood after reading the description of example embodiments given purely for information and being in no way limitative, with reference to the appended drawings in which:

FIGS. 1A-1E show different embodiments of an asymmetric planar double-gate;

FIG. 2 shows examples of curves for the simulation and measurement of a leakage current from an asymmetric double-gate structure as a function of the offset between its two gates;

FIGS. 3A-3E show an example method according to the invention for fabricating an asymmetric planar double-gate;

FIGS. 4A-4B show variant of the example method according to the invention for fabricating an asymmetric planar double-gate;

FIGS. 5A-5B show an example method for fabricating an asymmetric double-gate structure and a symmetric double-gate structure on the same substrate;

FIGS. 6A-6B show another example method for fabricating an asymmetric double-gate structure and a symmetric double-gate structure on the same substrate;

FIG. 7 shows an example of a 4T memory cell, provided with 4 asymmetric double-gate transistors that can be implemented using a method according to the invention;

FIG. 8 shows a portion of an example memory matrix provided with cells of the type shown in FIG. 7;

FIG. 9 shows another example of a 4T memory cell made using a technology complementary to that used for the cell in FIG. 7;

FIG. 10 shows another example of a 4T memory cell provided with 2 asymmetric double-gate transistors and 2 asymmetric double-gate transistors co-integrated on the same substrate.

FIG. 11A shows an example of how the channel current of a double-gate transistor varies as a function of the polarisation of its two gates;

FIG. 11B shows an example of how the channel current of an asymmetric double-gate transistor varies as a function of the polarisation of its two gates;

FIG. 12 shows another example of a 4T memory cell made using a technology complementary to that used for the cell in FIG. 11;

FIG. 13 shows an example of an 8T memory cell provided with 8 double-gate transistors including four asymmetric double-gate transistors and four symmetric double-gate transistors co-integrated on the same substrate;

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

We will now describe a detailed example of a method for making an asymmetric planar double-gate structure formed from two gates with different critical sizes or dimensions, with reference to FIGS. 3A to 3E.

The first step is to make a structure 150 formed from a stack like that shown in FIG. 3C comprising a first gate block 110 a, a first gate dielectric zone 109 a supported on the first block 110 a, a semiconducting zone 115 a supported on the first dielectric zone 109 a, a second gate dielectric zone 119 a supported on the semiconducting zone 115 a, a second gate block 120 a supported on the second dielectric zone 119 a, on a substrate 100. The second gate block 120 a may be based on a semiconducting material for example such as polysilicone that could be doped, while the first gate block 110 a may also be based on a semiconducting material for example such as polysilicone that could be doped. The dielectric zones 109 a and 119 a and the semiconducting zone 120 a are made with a critical size or dimension dc larger than the critical size or dimension dc₀ of the first gate block 110 a and the second gate block 120 a (the critical dimensions dc₀ and dc being defined in a direction parallel to the vector {right arrow over (i)} in the orthogonal coordinate system [O; {right arrow over (i)}; {right arrow over (j)}; {right arrow over (k)}] in FIG. 3C). A hard mask 130 based on a dielectric material, for example such as SiO₂ or Si₃N₄, may be mounted on the second gate block 120 a.

Such a structure 150 was made starting from a stack of thin layers made on a substrate 100, for example a semiconductor on insulator type substrate, said stack being formed from at least one first layer 110 of gate material, at least one layer 109 of dielectric material on the layer 110 of gate material, at least one semiconducting layer 115 on the dielectric layer 109, and at least one second layer 120 of gate material on the semiconducting layer 115. The layers 110 and 120 of the gate material may for example be formed based on polysilicone. The thickness of the first layer 110 of gate material may for example be between 10 and 100 nanometers, while the thickness of the second layer 120 of the gate material may be greater, for example between 5 nanometers and 50 nanometers (FIG. 3A).

The stack may then have been etched, for example by anisotropic etching, through the hard mask 130, so as to form the first gate block, the first dielectric zone, the semiconducting zone, the second dielectric zone and the second gate block, to make the structure 150. For example, the stack may be etched by anisotropic plasma etching based on HBr and oxygen (FIG. 3B).

A second etching may have been done, selective with respect to the semiconducting zone and dielectric zones, to reduce the lateral dimensions of the first and second gate blocks 110 a and 120 a. The second etching may for example be an isotropic plasma etching based on CF₄ (FIG. 3C).

The next step after obtaining the structure 150 (FIG. 3D) is to dope the second block 120 a using at least a first implantation selective with respect to the first block 110 a. Selective implantation means that an implantation of the second block 120 a is done without implanting the first block 110 a or implanting the first block 110 a less. In this example, the implantation is done such that the first block 110 a is not implanted close to the interface with the first dielectric zone 109 a or in a zone adjacent to the first dielectric zone 109 a. The dielectric zones 109 a and 119 a may protect at least part of the first block 110 a during the implantation step.

The selective implantation may be done so as to obtain implanted zones 121 a and 122 a in the second block 120 a, particularly in the regions of the second block 120 a located on the flanks of this block and adjacent to the second dielectric zone 119 a, while the first block is not implanted or is not implanted at least in the zone in the first block 110 a located adjacent to the first dielectric zone 120 a.

In this example, the implantation is inclined at a predetermined angle α with respect to a normal to the principal plane of the substrate 100 (the principal plane of the substrate being defined in FIG. 3D as being a plane passing through the substrate and parallel to the plane [O; {right arrow over (i)}; {right arrow over (k)}]). The implantation angle α may for example be between 7° and 45°. The critical dimension dc of the dielectric zones 109 a, 119 a, the corresponding heights h₁ and h₂ of the first gate block 110 a and the second gate block 120 a, and the implantation angle α may be selected so that the second gate block 120 a is doped, preferably without doping the first block 110 a. In order to implement this selective implantation, the structure 150 may be made such that the critical dimension dc of the first block 110 a and the second block 120 a is less than the critical dimension denoted dc₀ of zones 109 and 119 of the gate dielectric and the semiconducting zone 115. The critical dimensions dc and dc₀ may be such that dc₀−dc=l₂, in which for example l₂ is between 5 and 25 nanometers. Since the critical dimension of dielectric zones 109 a, 119 a is larger than the critical dimension of blocks 110 a and 120 a, zones 119 a and 109 a may provide protection for the first block during the inclined implantation, such that this first block is not implanted, or is not implanted close to the interface with the first dielectric 109 a. The dielectric zones 109 a, 119 a thus form an implantation mask for the first block 110 a. In order to implement this selective implantation, the blocks 110 a and 120 a may be designed such that the height h₂ of the second block 120 a is greater than the height h₁ of the first gate block 110 a (the heights h₁ and h₂ being dimensions defined in a direction parallel to the vector {right arrow over (j)} in an orthogonal coordinate system [O; {right arrow over (i)}; {right arrow over (j)}; {right arrow over (k)}] in FIG. 3C). The height h₂ of the second block 120 a may be chosen such that h₂ is less than or equal to (dc−dco)/tan α. The height h₂ of the second block 120 a may for example be between 5 nanometers and 50 nanometers. The height h₁ of the first block 110 a may for example be between 10 nanometers and 100 nanometers. The critical dimension D of the hard mask may be chosen to be greater than the critical dimension of the second block 120 a, so as to protect the upper part of this block during implantation. The critical dimension D of the hard mask may be such that D−dc=l₁, for example where l₁ is less than 30 nanometers. In this example, the implantation is a local implantation on the second block 120 a made on each side of the structure 150, in semiconducting zones located on the flanks of this second block 120 a and close to and/or in contact with the gate dielectric zone 109.

Doping by implantation is a predetermined type of doping, or it may be done with a predetermined species. In the case in which blocks 110 a and 120 a are based on polysilicone, it would for example be possible to do an N type doping with arsenic, for example at a dose of 3¹⁵ atoms·cm⁻² and an energy chosen as a function of the difference in the critical size or dimension required between the two gates. For example, it would be possible to use arsenic or phosphorus or antimony to implant a semiconducting block 120 a at 3 keV, for example formed from polysilicone P doped with a doping agent such as boron at an average level of 10²⁰ atoms·cm⁻³, to obtain a controlled difference in the dimension of the order of 3 nanometers on each side of the gate. According to one variant, the implantation could be a polysilicone implantation made with germanium.

The blocks 110 a and 120 a may have been doped before the selective implantation step, and for example may have been doped at the time that the semiconducting layers 110 and 120 were deposited. In this case, selective implantation of the second block 120 a provides a means of modifying doping of the second block 120 a, particularly in regions located at the flanks of the second block and in contact with the second dielectric zone 119 a, while doping of the first block 120 a is unchanged subsequent to said selective implantation, at least in a zone located in contact with the first dielectric zone 109 a.

The next step is selective etching between semiconducting zones that were implanted and semiconducting zones that were not implanted during the previously described step.

According to one example, the selective etching may be selective removal of an implanted semiconducting material N in the case in which the semiconducting zones 121 a and 122 a were N implanted, relative to non implanted P doped zones.

The following table shows an example of a plasma etching method that can create selectivity between a semiconducting material implanted with N type doping and a P doped material:

Cl2 SF6 Ps (W) Pb (W) P (mT) t (s) BT 60 — 750 150 30 5 ME 150 — 1000 0 4 15 OE 150 — 1000 0 70 30

In this table BT, ME, OE, denote Break Through, Main Etch, and Over Etch respectively.

With such a method, N doped zones, for example the semiconducting zones 121 a and 122 a of the first block, will be etched while the P doped zone will not be etched.

According to another example, the selective etching may be selective removal of a P or P+ implanted semiconducting material in the case in which the semiconducting zones 121 a and 122 a were P or P+ implanted, relative to non-implanted N doped zones.

According to another example, selective etching may be selective removal of an N+ implanted semiconducting material if the semiconducting zones 121 a and 122 a were N+ implanted, relative to non-implanted but P doped zones.

For example, selective etching with HNA (HF/HNO₃/CH₃COOH) may also be done in the case in which the semiconducting zones 121 a and 122 a are based on polysilicone and were N+ implanted.

For example, selective etching with HNA (HF/HNO₃/CH₃COOH) may also be done in the case in which the semiconducting zones 121 a and 122 a are based on polysilicone and were N+ implanted.

According to another example, the selective etching may be selective removal of an implanted semiconducting material in the case in which the semiconducting zones 121 a and 122 a were doped by implantation, relative to semiconducting zones that were not implanted and were not doped. For example, selective etching with TMAH (tetra-methyl ammonium hydroxide) is possible in the case in which the semiconducting zones 121 a and 122 a are based on polysilicone and were implanted with N doping. In this case, non-doped zones are etched more quickly than the implanted zones 121 a and 122 a.

Such an example is illustrated in FIG. 3E. Once selective etching has been done, the critical dimension of the first block 110 a that will form a first gate is dc₁, while the critical dimension of the second block 120 b that will form a second gate is dc₂ greater than dc₁, the implanted semiconducting zones 121 a and 122 a being less etched than the non-implanted semiconducting zones.

In the case in which the first block and the second block are based on polysilicone, the implantation done previously may be a germanium implantation in the polysilicone, so as to use a selective etching method for polysilicone implanted with germanium, relative to polysilicone, for example using an isotropic plasma etching based on CF₄.

Implantations may have been done before the selective implantation step to define extensions to the source and drain zones.

According to one variant of the example method described above, the implantation can be done on only one side of the structure 150 during the selective implantation step described above.

In FIG. 4A, a semiconducting zone 122 a is implanted on a flank of the second block 120 in contact with the gate dielectric 119, while the second block on the other side of a normal to the principal plane of the substrate 100 passing through the structure 150 is not implanted. The structure 150 is made such that the critical dimension of the first block and the second block is less than the critical dimension of the second isolating zone and/or the first isolating zone.

Once the selective etching of the gate structure has been made, the critical dimension of first block 110 a that will form a first gate is dc₁, while the critical dimension of the second block 120 b that will form a second gate is d′c₂ greater than dc₁ (FIG. 4B).

Another variant of one of the methods described above includes the production of an asymmetric double-gate structure provided with two gates with different compositions, and designed to have different output work done on them.

In this case, blocks 110 a and 120 a may for example be formed from a bilayer. The first block 110 a may for example be formed from a metallic layer for example based on TiN or TaN in contact with the first dielectric zone 109 and a layer of semiconducting material, for example based on polysilicone, on which the metallic layer is supported. The second block 120 a may also be formed from a bilayer comprising a metallic layer, for example based on TiN or TaN in contact with the second dielectric zone 119 and a layer of semiconducting material, for example based on polysilicone, supported on the metallic layer. The structure 150 is made such that the critical dimension of the first block and the second block is less than the critical dimension of the second and/or the first isolating zone.

The next step during selective implantation of the second block 120 a is to implant the semiconducting layer of the bilayer. The output work from the polysilicone semiconducting layer/metallic layer bilayer can be transferred to the semiconducting layer based on polysilicone. The implantation energy and the implantation annealing are adjusted such that the implantation reaches the centre of the gate so that the output work is adjusted over the entire surface area of the gate. Thus, asymmetric operating transistors can be made, for example with a gate length of the order of 20 nm, and a threshold voltage Vth1 for the first gate adjusted for example to 0.1 Volts, and a threshold voltage Vth2 for the second gate for example adjusted to 0.3 Volts giving a difference in the output work between the two gates for example of the order of 0.4 Volts.

Either of the methods described above can be used for production or co-integration of asymmetric planar double-gate transistors and symmetric planar transistors on the same support or on the same substrate 100.

This is done by making several structures on a substrate such as the substrate 100, for example a first structure 250 and a second structure 260 of the same type as the structure 150 previously described. Means of protection against an ionic implantation beam are made for the second structure 260, before carrying out the selective implantation step. These protection means may be formed from at least one layer 270 for example defined by photolithography and covering the second structure 260. For example, the protection layer 270 may be formed from a resin based layer or a hard mask, for example based on Si₃N₄ or SiO₂. The protection layer 270 comprises at least one opening exposing the first structure 250.

The second gate block of the first structure 250 is then implanted selectively (FIG. 5A), for example using the method described above with reference to FIG. 3D. The layer 270 protects the second structure 260 from the particle beam during this implantation.

The protection layer 270 is then removed, for example using O₂ plasma followed by chemical etching based on a mix of sulphuric acid and oxygenated water when this protection layer is based on resin.

The next step is to etch gate blocks of the first structure 250 and the second structure 260. This etching is selective etching of the implanted semiconducting zones 121 a, 122 a relative to the semiconducting zones that have not been implanted.

The first structure 250 and the second structure 260 supported on the substrate 100 are shown in FIG. 5B, once the etching has been done. The first structure 250 comprises a first block 110 a of a gate with critical dimension dc₁, and a second block 120 a that will form a second gate with critical dimension dc₂, the implanted semiconducting zones 121 a, 122 a having been etched less than the non-implanted semiconducting zones. Once the selective etching has been done, the second structure 260 comprises a first block 210 a that will form a first gate with a critical dimension dc₁, while the second block 220 b that will form a second gate has a critical dimension dc₁ identical to the first block. The first structure 250 is designed for an asymmetric double-gate transistor, while the second structure 260 made on the same substrate 100 as the first, is designed for a symmetric double-gate transistor. Steps to make spacers, to form source and drain regions and to make contacts may then be done to complete the formation of symmetric double-gate and asymmetric double-gate transistors.

A variant of the method described above with reference to FIGS. 5A-5B is given with reference to FIGS. 6A-6B. For this variant, a first structure 350 and a second structure 360 of the same type as structures 250, 260 described above, are made on the substrate 100, but comprise blocks 310 a, 320 a respectively formed from a bilayer, instead of the semiconducting blocks 110 a and 120 a.

The first block 310 a may for example be formed from a metallic layer 308 a, for example based on TiN or TaN in contact with the first dielectric zone 109 and a layer of semiconducting material 309 a for example based on polysilicone, on which the metallic layer 308 a is supported. The second block 320 a may also be formed from a bilayer comprising a metallic layer 318 a, for example based on TiN or TaN in contact with the second dielectric zone 119 a and a layer of semiconducting material 319 a, for example based on polysilicone, supported on the metallic layer 318 a.

In the same way as for the method described above with reference to FIG. 5A, a selective implantation of the second block 320 a of the first structure 350 (FIG. 6A) is done, particularly so as to obtain strongly doped semiconducting zones 321 a and 322 a in the layer of the semiconducting material 309 a of the first structure 350. During this implantation, the second structure 360 is protected by a protection layer 270, for example based on resin (FIG. 6A).

Then, the next step after removing the protection layer 270 is to selectively etch the semiconducting layers 309 a and 319 a of the bilayer with respect to the doped semiconducting zones 321 a and 322 a of the first structure 350. This etching may be isotropic and may for example be done using CF₄ based plasma.

The metallic layers 308 a and 318 a are then etched for example by chemical etching based on HCl and de H₂O₂. During this step, the polysilicone parts of the layers 309 a and 319 a are used as a mask for chemical etching (FIG. 6B).

The first structure 350 and the second structure 360 supported on the substrate 100 are shown in FIG. 6B, once the etching has been done. The first structure 350 comprises a first block 310 a with a given contact surface area with the first dielectric zone 109 a, while said second block 320 a has a larger contact surface area with the second dielectric zone 119 a than said given surface area. In the first structure 350, the critical dimension of the metallic layer 318 a of the second block 320 a in contact with the second dielectric zone 119 a is equal to dc2, while the critical dimension of the metallic layer 308 a of the first block 310 a in contact with the first dielectric zone 109 a is dc1, less than dc2.

Once the selective etching has been done, the second structure 360 comprises a first block that will form a first gate with a critical dimension dc₁, while the second block 320 a that will form a second gate has a critical dimension dc₁, identical to the critical dimension of the first block. The first structure 350 is designed for an asymmetric double-gate transistor, while the second structure 360 made on the same substrate 100 as the first, is designed for a symmetric double-gate transistor.

A method like that described above with reference to FIGS. 3A-3E may be used to implement a random access memory cell provided with asymmetric double-gate transistors. A cell provided with asymmetric double-gate transistors only can be made using such a method.

According to another possibility, a cell provided with asymmetric double-gate transistors and symmetric double-gate transistors co-integrated on the same support may be made, for example using a method like that described above with reference to FIGS. 5A-5B.

FIG. 7 shows an example of a random access memory cell 300 provided with asymmetric double-gate transistors implemented using a method for example like that described above with reference to FIGS. 3A-3E.

This memory cell 300 is a 4T type SRAM static memory cell provided with 4 double-gate transistors, for example made using the MOS technology. The cell 300 comprises a first plurality of transistors forming a first inverter and a second inverter connected according to a “flip-flop” configuration. The first plurality of transistors may be formed from a first asymmetric double-gate charge transistor TL1 _(T), and a second asymmetric double-gate charge transistor TL1 _(F). The charge transistors TL1 _(T) and TL1 _(F) may be made using a given first type of MOS technology, for example a PMOS type technology. The two gates of the first charge transistor TL1 _(T) are connected to each other, while the two gates of the second charge transistor TL1 _(F) are also connected to each other. The double-gate of the second charge transistor TL1 _(F) is also connected to a first storage node T of the first cell 300, while the double-gate of the first charge transistor TL1 _(T) is also connected to a second storage node F of the first cell 300. The sources of the charge transistors TL1 _(T), TL1 _(F), may be connected to each other and to a power supply potential VDD, while the drain of the first charge transistor TL1 _(T) may be connected to the first node T and the drain of the second charge transistor TL1 _(F) is connected to the second node F. The charge transistors TL1 _(T) and TL1 _(F) are designed to maintain a charge necessary to set up a given logical level, for example a level ‘1’, for example corresponding to a potential equal to the power supply potential VDD on either of the nodes T or F, as a function of the logical value memorised in the cell 300. The first cell 300 is also provided with a first asymmetric double-gate access transistor TA1 _(T), and a second asymmetric double-gate access transistor TA1 _(F). The access transistors TA1 _(T), TA1 _(F) may for example be of the NMOS type. The first access transistor TA1 _(T), and the second access transistor TA1 _(F) each comprises a first gate connected to a first word line WL. The second gate of the first access transistor TA1 _(T), is connected to the first storage node T, while the second gate of the second access transistor TA1 _(F) is connected to the second storage node F. The source of the first access transistor TA1 _(T), is connected to a first bit line BL_(T), while the source of the second access transistor TA1 _(F) is connected to a second bit line BL_(F). The drain of the first access transistor TA1 _(T) is connected to the first storage node T, while the drain of the second access transistor TA1 _(F) is connected to the second storage node F. The access transistors TA1 _(T), TA1 _(F) are arranged to allow access to storage nodes T and F, during a read or write phase of cell 300, and to block access to cell 300 when the cell 300 is in an information retention mode. Such a cell 300 can give an improved margin against static noise and an improved compromise between stability in retention and stability in reading. In this example, the information stored in retention is also maintained without making use of refreshment means. The word line WL is controlled as a function of the mode in which it is required to place the cell 300.

The following describes an example operation of such a cell 300:

In retention mode, bit lines BL_(T), BL_(F) are connected to a potential VSS while the word line WL is also kept at potential VSS to stabilise a memorised data. Access transistors TA1 _(T) and TA1 _(F) are in a blocked state. In the case in which the first node T is at a high logical level and the second node F is at a low logical level, the second charge transistor TL1 _(F) is also blocked, and only the first charge transistor TL1 _(T) is conducting. The current passing through the second access transistor TA1 _(F) must be greater than the sum of the current passing through the second charge transistor TL1 _(F) and the gate current output from the first charge transistor TL1 _(T), to keep the potential of the second node F close to VSS. Connecting the second gate of the second access transistor TA1 _(F) to the first storage node T set to VDD, increases its leakage current for example by 2 to 3 decades and thus guarantees good stability in retention. The use of asymmetric double-gate architecture transistors can satisfy this condition, provided that the threshold voltage of the second access transistor TA1 _(F) is less than the threshold voltage of the second charge transistor TL1 _(F), taking account of polarisation conditions.

In read mode, the bit lines are initially charged or precharged to a potential VSS. The word line is then polarised at a potential VDD selected so as to enable access to storage nodes T, F. The stability of the cell 300 in read mode depends on the relation between conduction currents of transistors TL1 _(T) and TA1 _(T). The conduction current that passes through the first access transistor TA1 _(T) is made less than the conduction current of the first charge transistor TL1 _(T), to maximise the margin against noise. The connection of the second gate of the first access transistor TA1 _(T) to the storage node F at zero voltage limits the current in the conducting state of the first access transistor TA1 _(T) and thus guarantees good stability of the cell 300 in read. This condition can be satisfied by using double-gate architecture transistors because, taking account of polarisation conditions in read mode, the first access transistor TA1 _(T) will have one channel while the second charge transistor TL1 _(T) will have two channels.

In write mode, for example to write a logical value ‘0’ on the first node T such that T=0, and F=1, the second bit line BL_(F) is initially charged or precharged to a potential VDD while the first bit line BLT is kept at a potential VSS. The word line WL is then polarised at potential VDD to activate access transistors TA1 _(T) and TA1 _(F) so as to connect the storage nodes to the bit lines.

The memory cell 300 that has just been described may be integrated into a memory matrix as shown in FIG. 8. This FIG. 4 shows cells 300 ₁, 300 ₂, 300 ₃, 300 ₄ of a memory matrix among N cells (where N>0) of the same type as cell 300. The memory matrix is formed from p columns, each column comprising m cells of the same type as cell 300. In this example, each of the columns in the matrix comprises two bit lines BLT₀, BLF₀, BLT₁, BLF₁, . . . , and is controlled by a column decoder. The m*p memory cells are controlled by m word lines WL₀, WL₁, . . . .

FIG. 9 shows a second example of a cell 320 with four transistors complementary to the first cell 300 described above. Such a cell 320 may also be made using a method according to the invention. In this example charge transistors are replaced by conduction transistors TD1T, TD1F, for example asymmetric double-gate NMOS transistors. The conduction transistors TD1T, TD1F are connected at VSS. The cell 320 is also provided with access transistors TA2 _(T), TA2 _(F) made using a technology complementary to the technology used for the access transistors in the first cell 300, and may for example be of the PMOS type.

According to one variant embodiment, a memorised data refreshment device may be associated with the cell in a case in which it is required to give priority to stability of the cell in read mode. The cell then behaves dynamically.

The stability of the cell in read mode can be improved without deteriorating the stability in retention, by reducing the potential of the word line WL activated in read.

It is also possible to co-integrate asymmetric and symmetric transistors using a method for example of the type described above with reference to FIGS. 5A-5B, in order to improve the global stability of the memory cell.

FIG. 10 shows a third example of an SRAM cell 340 with 4 transistors implemented with a method according to the invention. This third cell 340 is different from the first cell 300 in that it comprises a first symmetric double-gate charge transistor TL2 _(T), and a second charge transistor TL2 _(F), also a symmetric double gate transistor. Symmetric double-gate and asymmetric double-gate transistors are thus co-integrated into the same memory cell. This improvement can increase the ratio between the current in the conducting state and the current in the blocked state I_(ON)/I_(OFF) of the charge transistors. The quantity of charge to be evacuated in the bit line BL_(T) through the access transistor TA1 _(F) becomes smaller in retention mode, and the discharge from node T in read mode is more strongly compensated by the first charge transistor TL1 _(T).

FIG. 11A shows the electrical characteristics of a symmetric double-gate transistor. Two polarisation curves C31 and C32 are given in this figure. A first polarisation curve C31 is representative of the variation of the drain-source current Ids as a function of a potential Vg1 applied on a first gate of the transistor, when the second gate of the transistor is in a first polarisation state and a potential Vg2=0 Volts is applied on the second gate. A second polarisation curve C32 is representative of the variation of the drain-source current Ids as a function of a potential Vg1 applied on the first gate of the transistor when the second gate of the transistor is in a third polarisation state and a potential Vg2=VDD is applied on the second gate, where VDD is a power supply potential of the cell.

An asymmetric double-gate is formed from two distinct gates dissymmetric about the principal plane of the semiconducting active zone on each side of which these gates are placed. In a transistor provided with an asymmetric double-gate, the current output between the drain and the source of the transistor is different depending on whether the first gate or the second gate is active, even for the same polarisation.

FIG. 11B shows an example of the electrical characteristics of an asymmetric double-gate transistor implemented in a memory cell according to the invention. In this figure, the curves C₄₁, C₄₂ are representative of the change in the current passing through the active zone between the drain and the source as a function of a potential V_(G1) applied on the first gate for different fixed values of a potential V_(G2) applied on the second gate. The curve C₄₁ is given for a first potential value V_(G2) which in this example is equal to 0 volts, while the curve C₄₂ is given for a second potential value V_(G2) which in this example is 1 volt. In this example the second gate will not allow the transistor to output a current I_(ON) if it is active. This example of a transistor is characterised by two currents I_(ON) in the conducting state for a potential applied on the first gate VG₁=VDD and a potential applied on the second gate V_(G1) such that V_(G1)=V_(G2)=VDD and two currents I_(OFF) in the blocked state for V_(G1)=0V depending on whether V_(G2)=0V or VDD).

FIG. 12 shows a fourth example of an SRAM cell 360 with 4 transistors implemented using a method according to the invention. This fourth example cell 360 is different from the second example in that the cell 360 comprises a first double-gate conduction transistor TD2 _(T), in this case symmetric, and a second conduction transistor TD2 _(F) also a symmetric double-gate transistor.

We will now give comparative examples of the performances of the cell 300 described above relative to the performances of a cell with 6 transistors called a “standard 6T” implemented according to prior art. These comparative results were obtained for a 32 nm critical gate dimension technology. The compared cells were sized such that they have approximately the same read current ICELL. The cell 300 can give a much greater static noise margin (SNM) and write noise margin RNM than the static noise margin of the standard 6T cell. The SNM for the 4T cell is more than 40% better than the 6T cell, and its write margin is more than 50% better for an increase in the surface area of the order of 41%. The leakage currents are also less than 28%.

FIG. 13 shows another example of a random access memory cell provided with 8 double-gate transistors including several asymmetric double-gate transistors and several symmetric double-gate transistors implemented using a method according to the invention.

This cell reference 400 called “8T” is provided with four asymmetric double-gate access transistors, two charge transistors and two symmetric double-gate conduction transistors. The first access transistor and the second access transistor in this case are referenced TAW1 _(T) and TAW1 _(F) respectively, while the first bit line, the second bit line are referenced BL_(WT) and BL_(WF) respectively. The cell 400 comprises a word line WWL connected to the first gate of the first and second access transistors TAW1 _(T) and TAW1 _(F), and is also provided with a second word line RWL and two other bit lines BL_(RT) and BL_(RF). The cell 400, also comprises a third asymmetric double-gate access transistor TAR1 _(T), and a fourth asymmetric double-gate access transistor TAR1 _(F), for example made using the NMOS technology. The first gate of the third access transistor TAR1 _(T) and the first gate of the fourth access transistor TAR1 _(F) are connected to the second word line RWL. The second gate of the third access transistor TAR1 _(T) is connected to the first storage node T, while the second gate of the fourth access transistor TAR1 _(F) is connected to the second storage node F. The second word line RWL, the third and fourth bit lines _(BLRT) and BL_(RF) and the third and fourth access transistors TAR1 _(T), TAR1 _(F), are dedicated to read operations of the cell 400. The first word line WWL, the bit lines BL_(RT), BL_(RF), WBLT, WBLF and the first access transistor TAW1 _(T), and second access transistor TAW1 _(F) are dedicated to write operations. The cell 400 also comprises an additional conduction transistor TDR1 _(T) connected between the third access transistor and the ground, and another additional transistor TDR1 _(F) connected between the fourth access transistor and the ground.

DOCUMENTS CITED

-   [ILL05]: Article by G. Illicali et al, Planar Double Gate     Transistors with Asymmetric Independent Gates, SOI Conference     (2005). p. 126. -   [DEL01]: WO 03/021633A1. -   [KED01]: Article by J. Kedziersky et al, High-performance     symmetric-gate and CMOS-compatible V, asymmetric-gate FinFET     devices, page 19.5.1, IEDM 2001. -   [LU05]: Article by C H Lu, Characteristics and Mechanism of Tunable     Work Function Gate Electrodes Using a Bilayer Metal Structure on     SiO₂ and HfO₂, EDL vol. 26 (7), p. 445 (2005).

[MAT05]: Article by L. Mathew, Multiple Independent Gate Field Effect Transistor (MIGFET), VLSI 2005, page 200. 

1. A method for fabricating a microelectronic device with one or plural double-gate transistors, comprising: a) forming one or plural structures on a substrate including at least a first block configured to form a first gate of a double-gate transistor, and at least a second block configured to form a second gate of the double-gate transistor, the first block and the second block being located on opposite sides of at least one channel semiconducting zone and separated from the at least one channel semiconducting zone by a first gate dielectric zone and a second gate dielectric zone respectively, the first gate dielectric zone and the second gate dielectric zone, the at least one channel semiconducting zone, and the second block supported on the first block, the one or plural structures being made such that the first block and the second block have a critical dimension less than a critical dimension of the second gate dielectric zone and the first gate dielectric zone, wherein the critical dimension is defined as a width measured in a direction parallel to a principal plane defined by a surface of the substrate on which the one or plural structures is formed; and b) doping at least one or plural semiconducting zones in the second block of at least one given structure among the one or plural structures, using at least first implantation selective relative to the first block, the first dielectric zone and the second dielectric zone configured to protect at least part of the first block during the at least first implantation.
 2. A method according to claim 1, in which the at least first implantation is done at a non zero predetermined angle from a normal to the principal plane of the substrate passing through the at least one channel semiconducting zone.
 3. A method according to claim 1, in which the at least first implantation is done in zones in the second block located close to and/or in contact with the second dielectric zone.
 4. A method according to claim 1, in which the at least first implantation is done on a first side of the given structure, a part of the given structure on another side of a normal to the principal plane of the substrate passing through the at least one channel semiconducting zone not being implanted.
 5. A method according to claim 1, further comprising at least one selective etching c) between non-implanted semiconducting zones of the first and second blocks and implanted semiconducting zones of the second block after the doping b).
 6. A method according to claim 5, in which the selective etching is selective between non-doped semiconducting zones and semiconducting zones doped using the at least first implantation.
 7. A method according to claim 5, in which the selective etching is selective between semiconducting zones doped using a first doping and semiconducting zones doped by the at least first implantation using a second doping different from the first doping.
 8. A method according to claim 1, in which the first block is supported on the substrate, the first block, the at least one channel semiconducting zone and the second block being superposed on top of the substrate.
 9. A method according to claim 1, in which the second block is covered by a hard mask in the doping b), a critical dimension of the hard mask being larger than the critical dimension of the second block.
 10. A method according to claim 1, in which the first block and/or the second block are semiconductors.
 11. A method according to claim 1, in which the first block and/or the second block is formed from at least one metallic layer and at least one stacked semiconducting layer respectively.
 12. A method according to claim 2, in which the given structure is configured for an asymmetric double-gate transistor.
 13. A method according to claim 1, in which at least one particular structure among the one or plural structures formed in the forming a) is protected during the doping done in doping b), by at least one protection layer, and the at least one particular structure is configured for a symmetric double-gate transistor.
 14. A method for fabricating a random access memory cell provided with asymmetric double-gate transistors using a method according to claim
 1. 15. A method for fabricating a random access memory cell structure provided with asymmetric double-gate transistors and symmetric double-gate transistors using a method according to claim
 13. 16. A method according to claim 15, the random access memory cell structure being a static random access memory SRAM.
 17. A method according to claim 1, in which the at least first implantation is done in zones in the second block located in contact with the second dielectric zone. 